EP1076596A1

EP1076596A1 - Material feed container, especially for thick matter pumps

Info

Publication number: EP1076596A1
Application number: EP99922124A
Authority: EP
Inventors: Hellmut Hurr
Original assignee: Putzmeister AG
Current assignee: Putzmeister Concrete Pumps GmbH
Priority date: 1998-05-08
Filing date: 1999-04-10
Publication date: 2001-02-21
Anticipated expiration: 2019-04-10
Also published as: JP2002514496A; EP1076596B1; ES2188166T3; US6488477B1; WO1999058235A1; DE59903755D1; DE19820509A1

Abstract

The invention relates to a material feed container (20), especially for thick matter pumps, comprising a lower part (38) that is open towards the top and a motor-driven agitator (44) that extends through the lower part (38) of the container inbetween two side walls (50). In order to make the inside of the container easily accessible for cleaning and maintenance purposes, the agitator (44) is provided with a pivot bearing (56) and a drive motor (48) that form a structural unit which is detachably connected to the lower part (38) of the container. The container is also provided with a cap (40) that is open towards the top and bottom, can be detachably arranged on the top edge of the lower part (38) of the container and can be connected to the lower part (38) of the container and/or agitator unit if so desired. These measures make it possible to pivot or remove the cap (40) from/in relation to the lower part (38) of the container without the agitator unit or to remove it from the lower part (38) of the container with the agitator unit (38).

Description

Material feed container, especially for thick matter pumps

description

The invention relates to a material feed container, in particular for thick matter pumps, with a container bottom part which has a container bottom, an end wall, a rear wall and two opposite side walls and which is open at the top, and with a container part which extends between the two side walls and by means of a Axle shaft each in a rotary bearing which penetrates the side walls and which can be driven by at least one motor arranged on the outside of the container.

In a known material feed container, the agitator is mounted in two bearings fixed to the container and is driven by two hydraulic motors arranged on the outside of the container. The bearings and motors are firmly attached to the material feed container. In the case of a two-cylinder thick matter pump, the agitator in the material feed tank covers the pump switch and part of the pump openings. In order to be able to access these parts for maintenance purposes, for example, the agitator must also be removed. To dismantle the agitator and the motors, the agitator blades must first be removed from the agitator shaft before the axle shaft can be pulled out of the bearings. For this purpose, the fastening screws with which the agitator blades are fastened to the axle shaft must be loosened. After a long time Pump operation, the screws are usually so tight due to concrete deposits that they can only be removed with the help of a cutter.

Proceeding from this, the object of the invention is to improve the known material feed container in such a way that easier access to the components and wearing parts located in the container is made possible.

To achieve this object, the combination of features specified in claim 1 is proposed. Advantageous refinements and developments of the invention result from the dependent claims.

The solution according to the invention is based on the idea that the agitator, its bearing and the at least one motor form an assembly which, as such, is detachably connected to the lower part of the container.

According to a preferred embodiment of the invention, the rotary bearings are arranged in a respective bearing block for this purpose, while the side walls each have an upwardly open recess for the liquid-tight reception of one of the bearing blocks adapted in their outer contour to the inner contour of the recess. In order to ensure a torsion-free transmission of force between the bearing blocks and the lower part of the container, it is proposed according to an advantageous embodiment of the invention that the bearing blocks form-fit with the sides under the introduction of force parallel to the side walls. tenwalls are connectable. The recess advantageously has an edge portion which at least partially projects beyond the side wall on the outside of the container and has an inner contour adapted to the outer contour of the bearing block, it being possible for two parts of the edge portion lying opposite one another to be provided with openings which are connected to one another and with a transverse bore in the bearing block aligned and through which a clamping screw can be inserted to fix the bearing block in the recess. In this way, it is possible to separate the agitator assembly from the lower part of the container by loosening only two clamping screws, so that it can be lifted out of the lower part, for example with the aid of a lifting device or a crane.

A further advantageous embodiment of the invention provides that the axle shaft is detachably coupled to the output shaft of one motor at each of its ends which are passed through the bearings in a liquid-tight manner. The motors can be flanged to the adjacent bearing block with their motor housing. In order to be able to absorb the high torques which occur when concrete is being stirred, the motors expediently have a torque support which projects essentially radially beyond the motor housing and can be positively anchored to the relevant side wall.

According to a further preferred embodiment of the invention, a detachable mountable on the upper edge of the lower container part, optionally connectable to the lower container part and / or to the bearing holders, is upwards and open container attachment provided below. With this measure, the container height can be increased and at the same time it can be achieved that the container attachment can be removed from the lower part of the container, either with or without an agitator assembly, for cleaning and maintenance purposes, for example.

The bottom part of the container and the top part of the container can advantageously be connected to one another at flange portions projecting in the edge region of the front and rear walls. For this purpose, the flange section projecting on the rear wall of the lower container part expediently has at least two open edges and the flange section projecting beyond the end wall has at least two closed openings for the passage of one flange screw penetrating the flange section of the container attachment. In order to be able to pivot the container attachment with respect to the lower part of the container, at least the flange screws on the end wall are flanged to the container attachment.

According to a further advantageous embodiment of the invention, the container attachment can be detachably connected to one of the bearing blocks in each case via flange portions projecting outwards in the region of its lower edge on the side wall side. For this purpose, the container attachment has in the region of its flange section projecting at the side wall at least one bore for a fastening screw aligned with a screw bore of the bearing block.

For liquid-tight sealing of the container in the area of the agitator bearings, it is advantageous if see the contour of the separating surfaces of the bearing block and the recess, a circumferential sealing ring is arranged. The sealing ring is expediently inserted into a circumferential groove in the bearing block.

The container attachment can be provided with a grating extending over the through opening, which is either rigidly connected to the container attachment or can be pivoted relative to the container attachment about an axis arranged on the end wall and parallel to the upper end wall edge.

The invention is explained in more detail below with reference to an exemplary embodiment shown schematically in the drawing. Show it

Figure 1 is a side view of a mobile concrete pump with a rear material feed container.

FIG. 2 shows a detail of the two-cylinder thick matter pump according to FIG. 1 with an agitator arranged in the material feed container in a diagrammatic representation;

3a shows a side view of the material feed container according to FIG. 2 with the container attachment attached;

FIG. 3b shows a side view corresponding to FIG. 3a with a raised assembly consisting of a container attachment and an agitator; FIG. 3c shows a side view of the material feed container according to FIG. 3a with the container attachment opened;

Fig. 4 is an end view of the material feed container according to Fig. 3a in a partially sectioned illustration.

1 consists essentially of a chassis 10, a front cab 12, a concrete placing boom 16 mounted on a pivot bracket 14 of the chassis and a two-cylinder thick matter pump 18 arranged in the rear part of the chassis Part of the chassis 10 arranged material feed container 20 is part of the two-cylinder thick matter pump 18, the feed cylinder 22 are connected to the material feed container via feed cylinder openings 24 in the rear wall 26. On the end wall 28 of the material feed container 20 opposite the rear wall 26 there is a pressure connection 30, to which the feed line 32 of the thick matter umpe is connected. In the interior of the container there is a pipe diverter 34 designed here as an S-tube, which is connected at one end to the pressure port 30 and the other end of which can be pivoted alternately about the axis of a pivot shaft (not shown) by hydraulic means in front of the two feed cylinder openings 24.

The material feed container 20 is subdivided into a container lower part 38 and a container attachment 40, which over a flange connection 42 are releasably connected to one another. In the material container there is an agitator 44, the axle shaft 46 of which is driven by external hydraulic motors 48 and extends through the interior of the container between the side walls 50 of the lower part of the container. The axle shaft 46 carries helical agitator blades 52 which mix the viscous material located in the material feed container 20 and at the same time convey it to the feed cylinder openings 24. The ends of the axle shaft 46 pass through a rotary bearing 56, which is arranged in a bearing block 58. The hydraulic motors 48 are rigidly fixed with their housing on the outside of the associated bearing block 58 opposite the agitator blade 52 and with their output shaft 60 are non-rotatably coupled to the ends 54 of the axle shaft 46. In addition, the hydraulic motors 48 have a torque support 62 which projects radially beyond the motor housing and by means of which they can be positively supported on an abutment 64 arranged on the outside of the side walls 50. The agitator 44 with the bearing blocks 58 and the hydraulic motors 48 form an assembly which can be detachably fastened in the side walls 50 of the lower part of the container. For this purpose, the side walls 50 each have an upwardly open recess 66, which has an inner contour that is complementary to the outer contour of the bearing blocks 58. Each of the recesses has an edge portion 68 on the outside of the container projecting beyond the side wall 50 with an inner contour adapted to the outer contour of the bearing block 58 in question. Between the separating surfaces 69 of the bearing block 58 and the recess 66, which are coordinated in their contours, a running sealing ring 70 is arranged, which is inserted into a circumferential groove of the bearing block 58. To anchor the bearing blocks 58 in the recesses 66, two mutually opposite parts of the edge portion 68 projecting on the outside are provided with openings 72, which are aligned with one another and with a transverse bore 74 in the bearing block 58 and through which a clamping screw 76 for fixing the bearing block 58 in the recess 66 can be pushed through.

The lower container part 38 and the container attachment 40 are detachably connected to one another by means of flange screws 78, 80 via the flange parts 82, 84 on the rear wall and front wall side (FIG. 3a). For this purpose, the rear-side flange section 82 has two openings that are open at the edge, while the front-side flange section 84 is provided with closed openings. The flange bolts 78, 80 are articulated with their heads to tabs 86, 88 of the container attachment 40.

The container attachment 40 can also be releasably connected to the bearing blocks 58 via flange portions 90 projecting outward in the region of its lower edge, specifically with a fastening screw 92, which can be screwed into a threaded bore 94 located on the bearing block 58 through an opening in the relevant flange portion 90 . The sealing rings 70 running around the bearing blocks 58 lie in this area from below against the flange parts 90. The container attachment 40 is overlapped in the area of its continuous opening by a grating 96 which is rigidly connected to the container attachment 40 or can be pivoted relative to the latter about an end axis.

With the measures according to the invention, it is possible, by loosening the fastening screws 92 and the flange screw 78, to pivot the container attachment 40 together with the grating 96 about the end axis formed by the tabs 88 and the flange screws 80 relative to the container lower part 38 (FIG. 3c).

In this way, it is possible to spray the material feed container for cleaning purposes after a pumping process has been carried out. In this case, the agitator 44 remains in the lower container part 38.

For maintenance purposes in the area of the tube switch 34, it is desirable that the agitator 44 is also removed from the container. With the measures described above, the agitator 44 can be lifted off the lower container part 38 together with the container attachment 40 (FIG. 3b). For this purpose, only the four flange screws 78, 80 and the two tensioning screws 76 have to be loosened and the container attachment 40 together with the agitator 44 can be lifted off the container lower part 38, for example with the aid of a crane. After the maintenance work has been carried out, the container attachment 40 with the agitator 44 can then be placed back onto the lower container part 38 in the reverse order in a few simple steps. In summary, the following can be stated: The invention relates to a material feed container 20, in particular for thick matter pumps, with an upwardly open lower container part 38 and a motor-driven agitator 44 which extends between two side walls 50 through the lower container part 38. In order to make the interior of the container easy to access To allow for maintenance and cleaning purposes, it is proposed according to the invention that the agitator 44, its pivot bearing 56 and its drive motor 48 form an assembly which as such is detachably connected to the lower container part 38. In addition, a container attachment 40 is provided which can be detachably placed on the upper edge of the lower container part 38 and which can be optionally connected to the lower container part 38 and / or to the agitator assembly. With the measures according to the invention, it is possible to either pivot or lift the container attachment 40 without the agitator assembly relative to the lower container part 38 or to lift it from the lower container part 38 together with the agitator assembly.

Claims

claims

1. Material feed container, in particular for thick matter pumps, with an upwardly open container lower part (38) having an end wall (28), a rear wall (26) and two opposite side walls (50) and with one between the two side walls (50 ) extending agitator (44), which is mounted by means of an axle shaft (46) in a rotary bearing (56) penetrating the side walls (50) and can be driven by at least one motor (48) arranged on the outside of the container, characterized in that the agitator (44) , whose rotary bearing (56) and the at least one motor (48) form an assembly which, as such, is detachably connected to the lower container part (38).

2. Material feed container according to claim 1, characterized in that the pivot bearings (56) are each arranged in a bearing block (58), and that the side walls (50) each have an upwardly open edge recess (66) for receiving one of them in their Have outer blocks (58) matched to the inner contour of the recess (66).

3. Material feed container according to claim 2, characterized in that the bearing blocks (58) can be positively connected to the side walls (50) with the introduction of force parallel to the side walls (50).

4. Material feed container according to claim 2 or 3, characterized in that the recess (66) has an at least partially over the side wall (50) on the outside of the container projecting edge portion (68) with an inner contour adapted to the outer contour of the bearing block (58).

5. Material feed container according to claim 4, characterized in that two mutually opposite parts of the edge part (68) are provided with openings (72) which are in alignment with one another and with a transverse bore (74) located in the bearing block (58) and through which a clamping screw ( 76) for fixing the bearing block (58) in the recess (66).

6. Material feed container according to one of claims 1 to 5, characterized in that the axle shaft is releasably coupled to the output shaft (60) each having a motor (48) at its ends (54) which are guided through the pivot bearing in a liquid-tight manner.

7. Material feed container according to one of claims 1 to 6, characterized in that the motors (48) are flanged to the outside with their motor housing on the adjacent bearing block.

8. Material feed container according to claim 6 or 7, characterized in that the motors (48) a substantially radially projecting beyond the motor housing, positively on the relevant side wall (50) have anchorable torque arm (62).

9. material feed container according to one of claims 1 to 8, characterized by a detachably attachable to the upper edge of the lower container part (38), optionally connectable to the lower container part (38) and / or to the bearing blocks (58), open top and bottom container attachment ( 40).

10. Material feed container according to claim 9, characterized in that the lower container part (38) and the container attachment (40) on in the edge region of the end wall (28) and the rear wall (26) projecting flange portions (84, 82) can be detachably connected to one another.

11. Material feed container according to claim 10, characterized in that the over the rear wall (26) of the lower container part (28) projecting flange section (82) at least one preferably open edge and the over the end wall (28) projecting flange section (84) at least one preferably closed opening Have a flange screw (78, 80) arranged on the container attachment (40) for the passage.

12. Material feed container according to claim 11, characterized in that at least the end wall flange screws (80) are articulated on the container attachment (40).

13. Material feed container according to one of claims 9 to 12, characterized in that the container attachment (40) can be releasably connected to one of the bearing blocks (58) via flange portions (90) projecting outward in the region of its lower edge on the side wall side.

14. Material feed container according to claim 13, characterized in that the container attachment (40) in the region of its side wall projecting flange portions (90) has at least one with a threaded bore (94) of the bearing block (58) aligned opening for a fastening screw (92).

15. Material feed container according to one of claims 2 to 14, characterized in that between the coordinated in their contours separating surfaces

(69) of the bearing block (58) and the recess (66) a circumferential sealing ring (70) is arranged.

16. Material feed container according to claim 15, characterized in that the sealing ring (70) is inserted into a circumferential groove of the bearing block (58).

17. Material feed container according to one of claims 9 to 14, characterized in that the container attachment (40) has a grating (96).

18. Material feed container according to claim 17, characterized in that the grating (96) rigid with the Container attachment (40) is connected.

19. Material feed container according to claim 17, characterized in that the grating (96) about an end wall near the flange portion (84) of the end wall (28) parallel axis relative to the container attachment (40) is pivotable.

20. Mobile concrete pump with a material feed container according to one of claims 1 to 19.